Control of Lysis of T4-infected Escherichia coli

The lysis of Escherichia coli B/5 infected with T4Dr48 could be delayed by addition of 9-aminoacridine (9AA). Infected cells showed an early period of maximal response followed by a decline in sensitivity. The ultimate rate of lysis was also affected by the dye. Deoxyribonucleic acid (DNA), protein, and lysozyme synthesis began at the normal time in complexes inhibited by 9AA addition. The rates of synthesis of these macromolecules were lower in the presence of the dye, with DNA and lysozyme synthesis being more strongly affected than total protein synthesis. Penicillin-sensitive cell wall synthesis stopped at about 10 min after infection. Inhibition of oxidative metabolism by early potassium cyanide addition prevented lysis in the presence of intracellular lysozyme. The cyanide-sensitive event occurred at about 20 min in normal infections, and between 30 and 40 min in 9AA-inhibited infections. 9AA could alter both the time at which the cyanide-sensitive event occurred and the time of lysis. Addition of chloramphenicol did not prevent lysis once intracellular lysozyme was present. Lysis from without of infected cells consisted of three phases: an initial sensitivity, followed by a short period of resistance, and then a return to sensitivity in normal infections. The demonstration of the late return to sensitivity depended on the presence of intracellular lysozyme, and could be delayed by 9AA addition.     

Lysis of Vibrio succinogenes by ethylenediamine-tetraacetic acid or lysozyme

Wolin, M. J. (University of Illinois, Urbana). Lysis of Vibrio succinogenes by ethylenediaminetetraacetic acid or lysozyme. J. Bacteriol. 91:1781-1786. 1966.-Cell suspensions of Vibrio succinogenes are lysed by ethylenediaminetetraacetic acid (EDTA) or lysozyme. Lysis occurs at alkaline pH and is prevented by 0.15 m NaCl or KCl or 0.3 m sucrose. The addition of 10(-3)m Mg(++), 10(-3)m spermine, or 10(-2)m Ca(++) prevents lysozyme lysis, and 10(-4)m spermine prevents EDTA lysis. EDTA lysis leads to the formation of a cell ghost, and lysozyme lysis leads to the formation of an empty round body. Freezing and thawing of cells permits lysozyme attack which is not prevented by the protective agents mentioned above. Much of the cell protein, and almost all of the nucleic acids, are released from the cells during EDTA lysis. Treatment of frozen-thawed cells with lysozyme at neutral pH does not cause release of more than 50% of the cell protein and 60% of the nucleic acids of the cells.     

Isolation and analysis of the protoplast membrane of Bacillus megaterium

1. Optimum conditions were found for the lysis of Bacillus megaterium KM by lysozyme. The age of culture, density of suspension and concentration of lysozyme affected the rate of lysis. 2. Protoplast membranes were isolated by centrifugation of lysates and were exhaustively washed. 3. Treatment with chloroform removed some lipid from the membranes, but about half of the total membrane lipid could be extracted only after partial acid hydrolysis. 4. The defatted membranes consisted of protein together with variable amounts of RNA; carbohydrate was almost absent. 5. Lipid accounted for 23% of the weight of the membrane, and included both neutral lipid and phospholipid. In both classes, branched-chain C(15) acids made up about 80% of the total fatty acid. 6. The phospholipid was a kephalin, and contained small quantities of several amino acids.     

Effect of retinol on the hemolysis and lipid peroxidation in vitamin E deficiency

A study on the effect of retinolin vitro on the hemolysis of vitamin E deficient rat red blood cells showed that retinol enhanced the lysis of the E deficient cells as compared to the lysis of normal cells. The lipid peroxidation present during hydrogen peroxide induced lysis of E deficient cells was however markedly inhibited in the presence of retinol without affecting the rate of lysis. In an actively peroxidising system of non-enzymatic lipid peroxidation of rat liver or brain homogenates and of brain lysosomes incubated with human erythrocytes, no lysis was obtained; incorporation of retinol in such systems resulted in lysis but no peroxidation. Hydrogen peroxide generating substances almost completely inhibited the lysis of normal human erythrocytes by retinol, but linoleic acid hydroperoxide and auto-oxidised liver or brain homogenates and ox-brain liposomes increased the lysis. It is concluded that vitamin E deficient erythrocyte hemolysis may be augmented by retinol, an anti-oxidant, having a lytic function without the peroxidation of stromal lipids     

Physicochemical Effects of Long Chain Fatty Acids on Bacterial Cells and their Protoplasts

S ummary . Fatty acids of chain length > C₁₀ induced lysis of protoplasts at pH 7·4 when the concentration was nearly bactericidal. At pH 6, lauric and linoleic acids produced lysis above bactericidal concentrations but, at pH 8, lysis was produced by the same acids below bactericidal concentrations. The lysis was immediate at pH 8, but at pH 6 the effect was preceded by contraction of protoplasts. At pH 7·4 the order of lytic activity between individual fatty acids was similar to that of bactericidal activity and the response of protoplasts of Bacillus megaterium relative to those of Micrococcus lysodeikticus reflected differences in bactericidal sensitivity though whole cells were much less sensitive to fatty acid-induced leakage effects than protoplasts. Reversal agents antagonized the lysis of protoplasts by fatty acids. A physicochemical basis for the action of fatty acids and reversal agents on protoplasts and whole cells is discussed.     

Characteristics and mechanism of IFN-gamma-induced protection of human tumor cells from lysis by lymphokine-activated killer cells

IFN-gamma has been shown to reduce the sensitivity of tumor cells to lysis by NK cells. The close relationship between NK cells and lymphokine-activated killer (LAK) cells has prompted us to investigate whether IFN-gamma pre-treatment also affects the sensitivity of tumor cells to lysis by LAK. We have shown previously that IFN-gamma can induce a significant reduction in the sensitivity of both cultured and fresh (surgically obtained) human tumor cells to lysis by LAK. Herein we show that changes in the sensitivity to LAK lysis of cultured human tumor cells can be induced by as little as 1 to 10 U/ml of IFN-gamma; a dose well within the range that can be achieved in vivo. Protection is induced within hours after treatment with IFN-gamma and is dependent on the continued presence of IFN-gamma. Tumor cells cultured in IFN-gamma for several days remain less sensitive to lysis and do not become refractory to IFN-gamma-mediated protection. In the absence of IFN-gamma, treated tumor cells regain "normal" sensitivity to lysis within 48 to 72 h. We have also investigated the mechanisms by which IFN-gamma reduces tumor cell sensitivity to LAK lysis using cold target competition, monolayer depletion, direct binding, and kinetic assays. IFN-gamma pre-treatment does not alter the kinetics of tumor cell lysis by LAK. Our data are most compatible with a model in which IFN-gamma reduces the ability of a subpopulation of tumor cells to induce the LAK effector cell to initiate lysis. These results are closely parallel to observations made on the IFN-mediated protection of targets from NK lysis and support the notion that NK- and LAK-mediated lysis are closely related. These results may have significance in vivo because high levels of IFN-gamma may be present at the tumor site or may be induced after therapeutic immunomodulation.     

Early Abortive Lysis by Phage BF23 in Escherichia coli K-12 Carrying the Colicin Ib Factor

Growth of phage BF23 was restricted in Escherichia coli K-12 strains carrying a colicin I factor (ColIb); most infected cells lysed early without producing progeny phages. Either addition of chloramphenicol before phage infection or ultraviolet irradiation of phage prevented early abortive lysis, an indication that certain phage functions are required for this phenomenon. Very little or no phage-induced lysozyme was synthesized in the infected ColI(+) cells. This result suggests that early abortive lysis was not due to the lysozyme action. A small fraction (0.05) of BF23-infected ColI(+) cells showed normal phage growth. This "escaped growth" may reflect the physiological state of the host bacteria rather than the heterogeneity of the infecting phage. Host-controlled modification was not observed. A phage mutant, BF23hI, able to grow on ColI(+) cells, was isolated and was characterized to be recessive to the wild-type BF23 in its ability to undergo early abortive lysis. Among the T series phages, T5 induced early abortive lysis, and growth of T5 was restricted upon infection to ColI(+) cells. These results and the other observations, including the occurrence of phenotypic mixing between BF23 and T5, suggest that these two phages are related to each other even though the receptor sites for BF23 and T5 are apparently different.     

Characteristics of a Lytic Enzyme Induced by Bacteriophage Infection of Micrococcus lysodeikticus

A lytic enzyme induced in Micrococcus lysodeikticus strain 1 by infection with N1 bacteriophage was purified 45- to 50-fold by ammonium sulfate precipitation, acid precipitation, and selective adsorption of contaminating proteins with calcium phosphate gel. The optimal pH for activity of the enzyme was 6.5 to 7.0. Maximal activity occurred at 45 to 50 C and at an ionic strength of 0.06. The enzyme had a limited specificity and lysed cell walls of M. lysodeikticus with the release of dinitrofluorobenzene reactive groups. Living cells were lysed in the absence of phage; however, the rate of lysis increased when phage was present in excess of 10 particles per bacterial cell. Young cells were most sensitive, and the sensitivity decreased to a minimum with stationary-phase cells. Acting synergistically, lysozyme and the N1-induced lysin caused lysis of cells which were resistant to either enzyme acting independently. The N1 lysin did not exhibit proteolytic activity.     

Inducible expression of a toxic poliovirus membrane protein in Escherichia coli: comparative studies using different expression systems based on T7 promoters.

The poliovirus 3AB gene has been cloned and overproduced in T7 expression vectors using different approaches to allow reduction of basal levels of expression. Expression of the poliovirus 3AB gene is highly toxic for E. coli cells, due to drastic changes induced in membrane permeability of the bacteria that lead to cell lysis when the T7 lysozyme is present. The best production of 3AB was achieved with the T7/lac system in cells lacking T7 lysozyme, where this toxic protein was synthesized to high levels and during several hours in the absence of cell lysis. These results show the efficient synthesis of a highly damaging membrane protein and open the possibility to apply heterologous gene expression in E. coli to other lytic proteins.     

Envelope-associated folded chromosomes for Escherichia coli: variations under different physiological conditions.

The folded chromosome of Escherichia coli has been investigated under various lysis and physiological conditions. A new gradient system was devised that allows excellent separation between unlysed cells and envelope-associated and envelope-free chromosomes. Isotope incorporation experiments showed that the fraction often called "membrane-bound nucleoids" contains cell wall in addition to nucleic acids, membranes, and proteins. The amount of lysozyme added and the lysozyme digestion time were found to be important when comparing the rate of sedimentation of envelope-associated chromosomes obtained under various physiological conditions. Amino acid-starved cells were found to be much harder to lyse with lysozyme than exponentially grown cells, The difference in sedimentation coefficient of envelope-associated chromosomes described earlier (Ryder and Smith, 1974) was not detected when the latter two types of cells had been given equivalent, but not identical, lysozyme treatment such that detergent-mediated lysis proceeded at the same rate. Analysis of pulse- and uniformly labeled chromosomes from amino acid-starved cultures revealed no preferential labeling of either envelope-associated or -released nucleoids. Nor was there a difference in sedimentation coefficient between uniform and pulse-labeled envelope-associated nucleoids. These results are in disagreement with the models for chromosome replication of Worcel and Burgi (1974) and Ryder and Smith (1974), respectively. Growing cells on carbon sources poorer than glucose demonstrated that the replicating chromosomes sediment faster than the bulk of envelope-associated nucleoids. The slower the growth rate, the greater this difference became. An alternative hypothesis regarding chromosome replication and its association with the cell envelope is presented.     

Roles of bacteriophage T4 gene 5 and gene s products in cell lysis.

Previous studies indicated that (i) T4 gene s product (gps) protects infected cells from superinfection lysis from without, (ii) the absence of gps in infected cells also leads to lysis from within even when T4 e lysozyme is absent, (iii) T4 gene 5 product (gp5), a polypeptide of the virion baseplate, may be responsible for inducing lysis from without, and (iv) altered gp5 of the T4 mutant 5ts1 can replace e lysozyme to cause lysis from within. Results of this study showed that (i) wild-type gp5 in infected cells lacking e lysozyme was responsible for lysis from within in the absence of gps, and (ii) gps did not protect infected cells from superinfection lysis from without by 5ts1 phage. We prpose that gps normally prevents functional expression of wild-type gp5 activity from either side of the cell wall, whereas the 5ts1 form of gp5 is insensitive to the gps barrier and induces lysis from either side of the cell wall.     

Use of bacteriophage T7 lysozyme to improve an inducible T7 expression system

Bacteriophage T7 lysozyme, a natural inhibitor of T7 RNA polymerase, can reduce basal activity from an inducible gene for T7 RNA polymerase and allow relatively toxic genes to be established in the same cell under control of a T7 promoter. Low levels of T7 lysozyme supplied by plasmids pLysS or pLysL, which are compatible with the pET vectors for expressing genes from a T7 promoter, are sufficient to stabilize many target plasmids and yet allow high levels of target protein to be produced upon induction of T7 RNA polymerase. Higher levels of lysozyme supplied by plasmids pLysE or pLysH reduce the fully induced activity of T7 RNA polymerase such that induced cells can continue to grow and produce innocuous target proteins indefinitely. Different configurations of the expression system can maintain several different steady-state levels of target gene expression. The presence of T7 lysozyme has the further advantage of facilitating the lysis of cells in preparing extracts for purification of target gene products.     

Statistical optimization of the lysis agents for Gram-negative bacterial cells in a microfluidic device

Through statistically designed experiments, lysis agents were optimized to effectively disrupt bacterial cells in a microfluidic device. Most surfactants caused the efficient lysis of Gram-positive microbes, but not of Gram-negative bacteria. A Plackett-Burman design was used to select the components that increase the efficiency of the lysis of the Gram-negative bacteriaEscherichia coli. Using this experimental design, both lysozyme and benzalkonium chloride were shown to significantly increase the cell lysis efficiency, and ATP was extracted in proportion to the lysis efficiency. Benzalkonium chloride affected the cell membrane physically, while lysozyme destroyed the cell wall, and the amount of ATP extracted increased through the synergistic interaction of these two components. The two-factor response-surface design method was used to determine the optimum concentrations of lysozyme and benzalkonium chloride, which were found to be 202 and 99 ppm, respectively. The lysis effect was further verified by microscopic observations in the microchannels. These results indicate that Gram-negative cells can be lysed efficiently in a microfluidic device, thereby allowing the rapid detection of bacterial cells using a bioluminescence-based assay of the released ATP.     

Antimicrobial Actions of Hexachlorophene: Lysis and Fixation of Bacterial Protoplasts

Hexachlorophene was found to be both a lytic and a fixative agent for protoplasts isolated from Bacillus megaterium. Concentrations of 50 to 100 mug of drug per mg of original cell dry weight were required to lyse 4.4 x 10(9) protoplasts (2 mg of original cell dry weight). At higher drug concentrations, protoplasts became fixed against osmotic stress and reduced in sensitivity to disruption by n-butanol. Lower drug concentrations caused proportionate lysis in the protoplast population. Intact cells lost the ability to become plasmolyzed at these same hexachlorophene concentrations. Nonplasmolyzed, drug-treated cells were resistant to the action of lysozyme, whereas plasmolyzed, drug-treated cells were sensitive. But the sensitivity of isolated cell walls to lysozyme digestion was not markedly altered by hexachlorophene treatment. These effects appeared to be secondary in the killing of cells by hexachlorophene because they occurred at concentrations higher than the minimum lethal concentration.     

The use of EDTA or polymyxin with lysozyme for the recovery of intracellular products fromEscherichia. coli

Summary Escherichia coli cells taken from exponential and late stationary (or decline) phases of culture were very susceptible to lysis by EDTA/lysozyme. Log phase cells were most susceptible to lysis by polymyxin/lysozyme. Treatment ofE. coli with EDTA and lysozyme compared favourably with sonication as a method for release of intracellular protein. Concentration ranges for optimal lysis were 100–800 μg/ml for EDTA and 25–50 μg/ml for lysozyme.     

Effects of a Quaternary Ammonium Compound on Escherichia coli

Increasing amounts of tetradecyldimethylbenzyl ammonium chloride (TAC) were lethal to an increasing proportion of an actively growing culture of Escherichia coli. The loss of nucleic acid material by actively growing E. coli did not appear to play a major role in the lethal effect. It was found that lag-phase cells were more sensitive than logarithmic-phase cells to the lethal effect of TAC. The effect of TAC on the lysozyme sensitivity of the test organism was compared with that obtained using disodium dihydrogen ethylenediaminetetraacetate (EDTA). Although TAC was found to render the test organism susceptible to lysozyme, the degree of lysis never reached that attained with EDTA.     

Method for the lysis of Gram-positive, asporogenous bacteria with lysozyme.

A method developed for the lysis of oral streptococci that employed the action of lysozyme suspended in dilute tris(hydroxymethyl)aminomethane-hydrochloride buffer containing polyethylene glycol has been adapted for use with lactobacilli, actinomycetes, propionibacteria, and pediococci. Most of the cellular deoxyribonucleic acid was liberated from many strains of bacteria usually thought to be lysozyme resistant. The major observations were as follows: (i) supplementation of the growth medium with L-threonine, L-lysine, or both frequently produced cells that were more susceptible to lysis by lysozyme; (ii) glucose-containing media produced cells that were more easily lysed than those from cultures grown on other substrates; (iii) polyethylene glycol not only served as an osmotic stabilizer, it also enhanced the extent of lysis; and (iv) dilute tris(hydroxymethyl)aminomethane buffer was superior to the buffer systems most commonly employed in published muramidase-based lysis techniques. Stationary-phase cells of Lactobacillus casei and Streptococcus mutans were more easily lysed than those isolated from log-phase cultures. The method as detailed in this report should be generally applicable for the lysis of gram-positive, asporogenous bacteria.     

Improved two-stage protein expression and purification via autoinduction of both autolysis and auto DNA/RNA hydrolysis conferred by phage lysozyme and DNA/RNA endonuclease

We report improved release of recombinant proteins in Escherichia coli, which relies on combined cellular autolysis and DNA/RNA autohydrolysis, conferred by the tightly controlled autoinduction of both phage lysozyme and the nonspecific DNA/RNA endonuclease from Serratia marcescens. Autoinduction occurs in a two-stage process wherein heterologous protein expression and autolysis enzymes are induced upon entry into stationary phase by phosphate depletion. Cytoplasmic lysozyme and periplasmic endonuclease are kept from inducing lysis until membrane integrity is disrupted. After cell harvest, the addition of detergent (0.1% Triton X-100) and a single 30 min freeze-thaw cycle results in >90% release of protein, green fluorescent protein. This cellular lysis is accompanied by complete oligonucleotide hydrolysis. The approach has been validated for shake flask cultures, high-throughput cultivation in microtiter plates, and larger scale stirred-tank bioreactors. This tightly controlled system enables robust growth and resistance to lysis in routine media when cells are propagated and autolysis/hydrolysis genes are only induced upon phosphate depletion.     

Characterization of lysozyme synthesized by differentiated mouse myeloid leukemia cells.

Lysozyme was induced by dexamethasone during normal differentiation of cultured mouse myeloid leukemia cells (M1) to macrophages and granulocytes. A large amount of lysozyme was produced by macrophage-like line cells (Mm-1), established from spontaneously differentiated macrophage-like cells from a clonal line of M1 cells. Lysozyme purified from the culture medium of these Mm-1 cells (Mm-1 lysozyme) had a molecular weight of 15,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and showed maximal activity at pH 6.6 with an optimal NaCl concentration of 0.04 M. Its mobility on polyacrylamide gel electrophoresis at pH 4.5 was distinctly lower than those of lysozymes from hen egg white and human urine. Rabbit anti-Mm-1 lysozyme serum inhibited the activities of lysozyme preparations from peritoneal macrophages of normal mice and rats and dexamethasone-induced differentiated M1 cells, but not those of preparations from hen egg white and human urine. Lysozyme was also purified from normal mouse lung, which is rich in alveolar macrophages and was found to be similar to lysozyme purified from the culture medium of Mm-1 cells in size and electrophoretic mobility and in its pH optimum, trypsin peptide map, and antigenicity. Thus the molecular structure of the lysozyme induced in differentiated mouse myeloid leukemia cells is similar to that of lysozyme produced by normal cells.     

Calcium enhances the hemolytic action of bile salts

The lysis of human erythrocytes by bile salts in buffer containing isotonic saline was dramatically enhanced by the addition of 5-10 mM calcium chloride. All bile acids tested showed this effect, with a marked increase in lysis occurring at 0.75 mM for deoxycholate, 1 mM for chenodeoxycholate, 2.5 mM for ursodeoxycholate and 5.5 mM with cholate in the presence of 10 mM calcium chloride. The effect appeared to be specific for calcium; strontium chloride and magnesium chloride gave no stimulatory effect. The increased lysis of the erythrocytes in the presence of 1 mM deoxycholate and 1-10 mM calcium chloride was not associated with increased uptake of the bile salt by the cells (measured with [14C]deoxycholate). Using erythrocytes previously labelled with [3H]cholesterol, there was no evidence of an enhanced removal of that membrane component in the presence of calcium and deoxycholate, compared to deoxycholate alone. The sensitivity of the cells to the effect of calcium in the presence of 1 mM deoxycholate increased with the length of time of their storage at 4 degrees C. The sensitivity returned to that of fresh cells after incubation at 37 degrees C with 30 mM adenosine plus 25 mM glucose, but this treatment did not further diminish the lysis. Lysis in the presence of 10 mM calcium chloride and 1 mM deoxycholate was partially blocked by increasing the KCl concentration at the expense of NaCl. The maximum effect occurred with a buffer comprising 100 mM KCl/50 mM NaCl. A more dramatic reduction in the lysis followed the incorporation of the calcium chelator, quin2, into the cells. The lysis induced by 1 mM deoxycholate in the presence of calcium was reduced by 80% in quin-2-loaded cells compared to controls. The data suggest that bile acids can promote the influx of calcium into erythrocytes, leading to lysis as a result of the efflux of intracellular potassium and/or the uptake of sodium from the incubation medium. The data further suggest that cellular effects may occur at lower bile acid concentrations than that thought to be required for detergent damage.